JPH06139675A - Drive device for disk storage medium - Google Patents

Abstract

(57) [Abstract] [Purpose] To reduce the size of a disk-shaped storage medium even if it is miniaturized, and to make this possible without significantly changing the conventional structure. [Structure] A plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, a disk-shaped storage medium and a disk-shaped storage medium to which a stack of spacers is fitted and which is located on one side of the fitted stack A hub having a surface that contacts the hub and a clamp that crimps the laminate to the surface of the hub, the spacer adjacent the hub or the disk adjacent the hub or the spacer adjacent the disk-shaped storage medium adjacent the clamp. Are provided, and these protrusions generate bending moments that oppose the bending moments that tend to bend the disk-shaped storage medium to keep the disk-shaped storage medium flat.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drive device for a disk type storage medium, and more particularly to a drive device suitable for rotating a disk which is a storage medium in a magnetic disk storage device.

[0002]

2. Description of the Related Art Conventionally, in a disk drive device in a magnetic disk storage device, a disk and a spacer are alternately laminated between a hub and a clamp, and the outer peripheral region of the clamp pushes the disk and the spacer in the laminating direction. And the spacer is fixed to the hub.

[0003]

In recent years, magnetic disk storage devices have become smaller and larger in capacity, and in terms of size, the mainstream is from 5 inches to 3.5 inches, and further 2.5 inches.
The size is shifting to smaller and thinner, and from a storage capacity perspective, for example, a 3.5-inch magnetic disk storage device has a larger capacity of 200 megabytes to 400 megabytes, and further to 1 gigabyte. Have been moved to. For this reason, the disk drive device must be made large in capacity within an extremely limited size, and it is required to be thin and small even if the number of mounted disks is increased to increase the storage capacity. ing.

However, the disk drive device in the conventional magnetic disk storage device, as described above, alternately stacks the disk and the spacer between the hub and the clamp, and stacks the disk and the spacer by the outer peripheral region of the clamp. The structure is such that the disc and the spacer are fixed to the hub by pushing in the direction, and even if the pressure from the clamp is uniform, the hub is deformed by the pressure of the clamp and the disc is bent in the radial direction. Therefore, when downsizing, the spindle motor also becomes smaller,
The rigidity of the hub is also reduced and the bending becomes even larger.

FIG. 8 shows an example of a disk drive device in a conventional magnetic disk storage medium having an in-hub type spindle motor. The hub A of the spindle motor is held by bearings D and E attached to a shaft C on a bracket B. A rotor hub F is fitted on hub A and shaft C. A stator G having a coil is attached to a portion of the shaft C located inside the hub, and a magnet rotor H is attached to the inside of the hub. The disks I to K are mounted on the hub A while being alternately stacked with the spacers L and M, and
A clamp N screwed to the hub A is pressed against the flange O of the hub.

When the clamp N is attached to the hub A, as shown in FIG.
As shown in FIG. 3, the hub flange O is extended outward by the pressure of the clamp N, the hub A is elastically deformed, the disks I to K and the spacers L and M are displaced, and the thickness of the disk, the number of spacers, and the hub Some or all of the disc bends due to mechanical strength. For example, when the mechanical strength of the hub becomes smaller due to the miniaturization, the contact point or contact surface between the disk I and the spacer M becomes outside the contact point between the disk I and the hub A, and the contact between the disk I and the spacer M. A bending moment M ₁ acting as a fulcrum of a point or a contact surface is generated by the restoring force of the hub, and the disk I bends so as to protrude toward the hub flange O or the bracket B, or the disk K contacts the clamp N. The point or contact surface is inside the disk K and the spacer L, and a bending moment M ₂ with the contact point or contact surface between the disk K and the spacer L as a fulcrum is generated by the restoring force of the hub. Bending so as to project toward the clamp N, or bending of the disk I or the disk K and the disk J To do

In addition, in order to increase the capacity, it is necessary not only to increase the recording density of data on the disk but also to increase the resolution of data recording. For this purpose, the flying height of the head is lowered. However, when the disc bends, the data area recorded on the disc is on the inner circumference side of the disc.Therefore, when the disc is made smaller, the bend in the data area becomes larger than that of a large-diameter disc, and the flying height of the head increases. Is low, the read voltages of the heads on the front and back sides of the disk are considerably different, and stable read accuracy cannot be obtained.

FIG. 10 shows the relationship between the head flying height of the disk adjacent to the hub and the flying height of the center rail portion which is the signal input portion. When the disk 1 bends, the slider P of the head located inside the bend
Is the flying heights h ₁₁ and h of the flying surfaces P ₁ and P ₂ of the slider.
_{Even if 21} is stable, the flying height hg ₁ of the center rail portion P ₃ which is the signal input portion of the head becomes relatively high. On the contrary, the slider Q of the head located outside the curve
Is the flying heights h ₁₂ , h of the air bearing surfaces Q ₁ , Q ₂ of the slider.
_{Even if 22} is stable, the flying height hg ₂ of the center rail Q ₃ which is the signal input portion of the head becomes relatively low. Therefore, there is a large difference in the signal read voltage of the head between the front and back of the disk 1, and especially for the slider P of the head located inside the bend, the flying height hg ₁ of the center rail portion, which is the signal input portion, is larger than the designed value. Since it is high, a sufficient head read voltage cannot be obtained.

As another disk type storage medium driving device, Japanese Patent Laid-Open No. 2-58781 discloses that a part of spacers arranged between the disks is made of an elastic material.
There is also a magnetic disk storage device that reduces the distortion of the disk due to the pressing force of the clamp,
Since it is not possible to obtain a highly accurate elastic material used as a spacer, and the dimensions change greatly depending on conditions such as temperature and pressure of the clamp, the dimensional precision of the spacers varies from device to device and the head floats. The amount varies, and it is difficult to stably manufacture a magnetic disk storage device having high read accuracy.

It is an object of the present invention to provide an improved disk-type storage medium drive which, even if it is miniaturized, has a small amount of disk bending and is capable of achieving this without drastically changing the conventional structure. To provide a device.

[0011]

DISCLOSURE OF THE INVENTION A drive device for a disk-shaped storage medium according to the present invention comprises a plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, a disk-shaped storage medium and spacers. A hub fitted with the laminate and having a surface for contacting a disk-shaped storage medium located on one side of the fitted laminate; and a clamp for crimping the laminate to said surface of the hub, the hub being located on said surface And a protrusion disposed outside the contact point or contact surface formed between the disk-shaped storage medium adjacent to the hub and the spacer adjacent to the disk-shaped storage medium by mounting the clamp. Is characterized by.

A disk-shaped storage medium driving device according to the present invention is provided with a plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a stack of the disk-shaped storage medium and the spacers. A disk storage medium adjacent to the hub, the hub including a hub having a surface for contacting the disk storage medium located on one side of the inlaid stack, and a clamp for crimping the stack to the surface of the hub. Adjacent spacers are located on the peeled surface of the disk-shaped storage medium adjacent to the hub and inside the contact point or contact surface formed between the hub and the disk-shaped storage medium adjacent to the hub by mounting the clamp. It is characterized in that it has protrusions arranged.

A drive device for a disk-shaped storage medium according to the present invention is provided with a plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a stack of the disk-shaped storage medium and the spacers. Includes a hub having a surface for contacting a disk-shaped storage medium located on one side of the fitted laminate, and a clamp for crimping the laminate to said surface of the hub, wherein the hub is located on and clamped to said surface. Is mounted between the disk-shaped storage medium adjacent to the hub and the spacer adjacent to the disk-shaped storage medium by the mounting of A spacer adjacent to the adjacent disk storage medium is located on the peeled surface of the disk storage medium adjacent to the hub and by mounting the clamp. It is characterized in that comprises a protruding disposed inside the contact points or contact surfaces are formed between the disk-shaped storage medium hub and adjacent thereto.

A drive device for a disk-shaped storage medium according to the present invention is fitted with a plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a laminate composed of the disk-shaped storage medium and the spacers. Includes a hub having a surface for contacting a disk-shaped storage medium located on one side of the fitted laminate, and a clamp for crimping the laminate to said surface of the hub, wherein the hub is located on and clamped to said surface. Is mounted between the disk-shaped storage medium adjacent to the hub and the spacer adjacent to the disk-shaped storage medium by the mounting of Adjacent to the hub, a plurality of spacers arranged in sequence are adjacent to the hub. On the surface of the disk-shaped storage medium facing away from the hub It is characterized in that it comprises a protruding, which is location.

A drive device for a disk-shaped storage medium according to the present invention is fitted with a plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a stack of the disk-shaped storage medium and the spacers. A disk-shaped storage medium adjacent to the clamp, the hub including a hub having a surface for contacting the disk-shaped storage medium located on one side of the inlaid laminate, and a clamp for crimping the stack to the surface of the hub. Adjacent spacers are located on the peeled surface of the disk-shaped storage medium adjacent to the clamp and inside the contact point or contact surface formed between the clamp and the disk-shaped storage medium adjacent to the clamp by mounting the clamp. It is characterized in that it has protrusions arranged.

A drive device for a disk-shaped storage medium according to the present invention is fitted with a plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a stack of the disk-shaped storage medium and the spacers. A spacer including a hub having a surface for contacting a disk-shaped storage medium located on one side of the fitted stack and a clamp for crimping the stack to said surface of the hub, but adjacent to the disk adjacent the clamp. Firstly, a plurality of spacers, which are sequentially arranged from the clamp to the hub, are formed between the clamp and the disk adjacent to the clamp by the mounting of the clamp on the surface of the disk-shaped storage medium adjacent to the clamp. It is characterized in that it is provided with a protrusion arranged inside the contact point or contact surface.

A drive device for a disk-shaped storage medium according to the present invention is fitted with a plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a laminate composed of the disk-shaped storage medium and the spacers. Includes a hub having a surface for contacting a disk-shaped storage medium located on one side of the fitted laminate, and a clamp for crimping the laminate to said surface of the hub, wherein the hub is located on and clamped to said surface. Is provided between the disk-shaped storage medium adjacent to the hub and the spacer adjacent to the disk-shaped storage medium by the mounting of the projection, and the protrusion is disposed outside the contact point or the contact surface, and the clamp is provided. The spacer adjacent to the adjacent disk storage medium is located on the peeled surface of the disk storage medium adjacent to the hub and is used for mounting the clamp. It is characterized in that it comprises a protruding disposed inside the contact points or contact surfaces are formed between the disk-shaped storage medium adjacent to the clamp and the clamp I.

A drive device for a disk-shaped storage medium according to the present invention is fitted with a plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a laminate composed of the disk-shaped storage medium and the spacers. Includes a hub having a surface for contacting a disk-shaped storage medium located on one side of the fitted laminate, and a clamp for crimping the laminate to said surface of the hub, wherein the hub is located on and clamped to said surface. A disk adjacent to the hub having a contact point formed between the disk-shaped storage medium adjacent to the hub and the spacer adjacent to the disk-shaped storage medium by mounting A spacer adjacent the storage media is located on the face of the disk storage media adjacent the hub and is attached to the hub by clamping. Adjacent to the hub is a spacer having a contact point or a protrusion formed inside the contact surface formed between adjacent disk storage media and adjacent to the clamp and adjacent to the disk storage media. A contact point formed on the peeled surface of the disk-shaped storage medium and between the clamp and the disk-shaped storage medium adjacent to the clamp by mounting the clamp, or a protrusion disposed inside the contact surface. It is characterized by being.

Further, the drive device for a disk-shaped storage medium according to the present invention comprises one disk-shaped storage medium and a hub having a surface for contacting the disk-shaped storage medium located on one side of the fitted disk-shaped storage medium. A clamp for crimping the disk-shaped storage medium to the surface of the hub, the hub being located on the peeled surface of the disk-shaped storage medium and the contact being formed between the clamp and the disk-shaped storage medium by mounting the clamp. It is characterized in that it is provided with a protrusion arranged outside the point or the contact surface.

[0020]

Since the disk storage medium is bent, and the degree of the bending is different depending on the thickness of the disk storage medium, the mechanical strength of the hub, and the like, only the hub is adjacent to the hub. Adjacent to the disc adjacent to the clamp only to the spacer adjacent to the disc, to the hub and adjacent spacers, to the spacers adjacent to the hub and adjacent disc to the clamps This spacer and the multiple spacers that line the hub,
A disk-shaped memory having protrusions on the spacer adjacent to the disk adjacent to the hub and the spacer adjacent to the disk adjacent to the clamp, the spacer adjacent to the disk adjacent to the hub and the hub, and the spacer adjacent to the clamp. It is used as a medium driving device.

In order to increase the storage capacity by increasing the number of mounted disks, when thinning and miniaturizing,
For example, when a disk-shaped storage medium adjacent to a hub bends, these projections are removed from the hub by having the drive device have projections only on the hub or only on the spacers adjacent to the disk adjacent to the hub. Let the point of application of pressure be outside the fulcrum formed by the contact point or contact surface between the disk adjacent to the hub and the spacer adjacent to this disk, and bend the disk-shaped storage medium adjacent to the hub. To generate a bending moment opposite to the bending moment M ₁
The above-mentioned working point and fulcrum are made clearer by preventing the bending of the disk-shaped storage medium adjacent to the hub and preventing the hub and the spacer adjacent to the disk adjacent to the hub from having a protrusion. become,
The generation of a bending moment opposite to the bending moment M ₁ is ensured. Further, when the disk-shaped storage medium adjacent to the hub and some of the disk-shaped storage media following it are also bent, the spacer adjacent to the hub and the disk adjacent to the hub and the spacer toward the clamp By having a drive device in which some of the spacers that are lined up are provided with protrusions, the points of action of the pressing force from the hub in each of the disc-shaped storage media to which these protrusions relate are brought into contact with the disc-shaped storage medium and the spacers. The bending moments M ₁ which are opposite to the bending moment M ₁ that bends each disk-shaped storage medium are generated by making them inside the fulcrum formed by the points or contact surfaces, and the bending of these disk-shaped storage media is prevented. To be done.

Further, when the disk-shaped storage medium adjacent to the clamp is bent, only the spacer adjacent to the disk adjacent to the clamp is provided with the protrusion so that the protrusion acts on the hub. The point is located inside the contact point or the fulcrum formed by the contact surface between the clamp and the disk-shaped storage medium adjacent to the clamp, and is opposite to the bending moment M ₂ for bending the disk adjacent to the clamp. The bending moment of the disk-shaped storage medium is prevented by generating the bending moment. When some disc-shaped storage media that follow the disc-shaped storage medium adjacent to the clamp also bend, some spacers that adjoin the disc adjacent to the clamp and some of the spacers that extend from this spacer toward the hub By causing the spacer and the drive device to have protrusions, the points of action of the pressing force from the hub on each of the disc-shaped storage media to which these protrusions relate are determined by the contact points between the clamp and the adjacent disc-shaped storage medium. Alternatively, a moment opposite to the bending moment M ₂ that bends the disk-shaped storage medium is generated by making it inside the fulcrum formed by the contact surfaces, and the bending of these disk-shaped storage media is prevented. .

Furthermore, when the disk-shaped storage medium adjacent to the hub and the disk-shaped storage medium adjacent to the clamp are bent, the drive device in which the hub and the spacer adjacent to the disk adjacent to the clamp have projections. These protrusions allow the point of action of the pressing force from the hub to be outside the fulcrum formed by the contact point or the contact surface between the disk adjacent to the hub and the spacer adjacent to this disk, and to the clamp. The point of action of the pressing force from the hub on the adjacent disk-shaped storage medium is made inside the contact point or the fulcrum formed by the contact surface between the clamp and the disk-shaped storage medium adjacent to the clamp, and these disk-shaped storage media To generate a moment opposite to the bending moments M ₁ and M ₂ that bend the medium , A disk-shaped storage medium is prevented from being bent, and a drive device is provided which includes not only a spacer adjacent to the disk adjacent to the hub and the clamp, but also a spacer adjacent to the disk adjacent to the hub, The generation of a moment opposite to the bending moment M ₁ is made more reliable.

Also, in the driving device having one disk type storage medium, the hub is provided with the protrusion, so that the point of action of the pressing force from the hub on the disk type storage medium is caused by the protrusion and the disk type storage medium. Since a bending moment M ₂ is generated outside the fulcrum formed by the contact point or the contact surface with the disk, the bending moment M ₂ bends so as to project the disk-shaped storage medium toward the clamp. The bending of the storage medium is prevented.

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a disk type storage medium driving device of the present invention will be described below with reference to FIGS.

The disk-type storage medium drive device is for supporting and rotating a disk as a storage medium in a magnetic disk storage device. FIG. 1 shows a disk drive device in a head disk assembly of a magnetic disk storage device. This head-disk assembly is used as a magnetic recording medium for a disk 1.
0 to 12, a spindle motor 13 for supporting and rotating the disk, a head 14 for writing data to the disk and reading data recorded on the disk, a head arm 15 for supporting the head, and a voice coil motor 16 for rotating the head arm. It is provided with a base 17 that supports the carriage actuator, the spindle motor and the carriage actuator, and a cover 18 that covers the base and seals these mechanical parts.

The spindle motor 13 is of the in-hub type and has a hub 21 and a bracket 22 as shown in FIG. The hub 21 is held by bearings 24, 25 attached to a shaft 23 on a bracket 22 and can rotate on the shaft. A rotor hub 26 is fitted on the hub 21 and the shaft 23. A stator 27 having a coil is attached to a portion of the shaft 23 located inside the hub, and a magnet rotor 28 is attached to the inside of the hub 21. By passing an electric current through the stator coil, the hub 21 causes the rotor magnet 28 to move.
I am allowed to rotate with.

The disk 10 is in direct contact with the flange 29 of the hub 21, the disk 11 has a spacer 30 between it and the disk 12, and the disk 12 is the disk 1.
It is fitted to the hub 21 with a spacer 31 interposed therebetween. A clamp 32 is attached to the rotor hub 26 and is fixed to the hub 21 by screws 33, and the disks 10 to 12 and the spacers 30 and 31 are crimped against the hub flange 29 so as to attach them to the hub 21.
It is fixed to.

Further, in this disk drive device,
The hub flange 29 is provided with a protrusion 21a, which allows, for example, the drive to be miniaturized and to prevent the bending of the disc that occurs when the mechanical strength of the hub is reduced. .

The protrusion 21a is located outside the contact point between the spacer 30 and the disk 10 that occurs when the clamp 32 is mounted, and is provided on the surface of the hub flange 29 where the disk 10 is peeled. The other areas of this surface and the entire area of the opposite surface from which the disk 11 has been peeled are formed flat, so that when the clamp 32 is installed, the hub 21 contacts the disk 10 only by the protrusion 21a, and the disk 10 is bent. A bending moment that cancels out the bending moment to be generated is generated to keep the disk 10 flat. That is, the clamp 32 is attached to the rotor hub 26, and the hub 2
When bolted to 1, the hub 21 is opened by the pressing force of the clamp 32 as described with reference to FIG.
The bending force M generated by the elastic force of the hub 21 acts on the contact point between the hub 21 and the disk 10, and the contact point between the disk 10 and the spacer 30 is a fulcrum.
₁ occurs, hub flange 29 or bracket 22
However, at this time, the protrusion 21a positions the contact point between the hub 21 and the disk 10 to the outside of the contact point between the spacer 30 and the disk 10. , The bending moment M _{1 ′} opposite to the moment M ₁ is applied to the spacer 30 and the disk 10.
It is generated using the contact point with the fulcrum as a fulcrum to prevent the disk 10 from bending.

FIG. 3 shows another configuration of the disk drive device of the magnetic disk storage device. This disk drive device is configured similarly to the disk drive device described with reference to FIG. 2, but the hub 21 does not have a projection, and only the spacer 30 has a projection, so that the disk 10 is bent. A moment opposite to the moment M ₁ to be generated is generated.

The hub 21 has the same structure as the hub of the spindle motor in FIG. 2, but the flange 29 is formed flat without protruding on the surface where the disk 10 is peeled. The spacer 30 is provided with the protrusion 30a only on the surface from which the disc 10 is peeled off, and the other region on this surface and the entire region of the opposite surface are formed flat, and the spacer 30 is brought into contact with the disc 10 only by the protrusion 30a. The protrusion 30 a is located inside the contact point between the hub 21 and the disc 10 that occurs when the clamp 32 is attached, and the protrusion 30 a is disposed on the spacer 30.
It is located on the peeled surface.

In the disk drive device thus constructed, the clamp 32 is mounted on the rotor hub 26, and the hub 2
1 is opened by the pressing force of the clamp 32, and the pressing force from the hub acts on the contact point between the hub 21 and the disk 10,
When the bending moment M ₁ generated by using the contact point between the disk 10 and the spacer 30 as a fulcrum causes the disk 10 to bend so as to project toward the flange 29 or the bracket 22 of the hub, the protrusion 30a causes the hub 2 to project.
The contact point between the disk 1 and the disk 10 is located outside the contact point between the spacer 30 and the disk 10, and the moment M ₁ is the same as in the disk drive device described with reference to FIG.
Since a bending moment M _{1 ′} that is opposite to the above is generated, the bending of the disk 10 is prevented.

FIG. 4 shows another configuration of the disk drive device of the magnetic disk storage device. The disk drive, as in the disk drive apparatus described in relation to FIG. 2, not only the hub 21 has a protrusion, and also is provided with a projecting spacer 30, the moment of moments M ₁ and opposite M It is made to the occurrence of the _{1 'to} more reliably.

Similar to the spindle motor hub in FIG. 2, the flange 21 of the hub 21 is provided with a protrusion 21a on the disk-side surface, and the other region on this surface is formed flat so that only the protrusion 21a is formed. To contact the disk 10. The spacer 30 is provided with a protrusion 30a on the surface from which the disc 10 is peeled off, and is formed flat on the other region of this surface and the entire region on the opposite surface so that the protrusion 21a alone contacts the disc 10. Has been forced to. Among these protrusions, the protrusion 21a is located outside the contact point between the clamp 32 and the disc 12 that occurs when the clamp 32 is mounted, and is located on the surface of the hub 21 where the disc 10 is peeled, and the protrusion 30a is the clamp 3
2 is provided inside the protrusion 30a of the hub 21 that occurs when 2 is mounted, and is provided on the surface of the spacer 30 from which the disk 10 is peeled.

Such a disk drive device is similar to the disk drive device described with reference to FIG.
2 is attached to the rotor hub 26 and bolted to the hub 21 so that the pressing force from the hub 21 is applied to the contact point between the disk 10 and the spacer 30 so that the disk 10 projects toward the hub flange 29 or the bracket 22. When a bending moment M ₁ that tends to bend is generated, the protrusion 21a on the hub flange 29 is
The point of action of the pressing force from the outer side of the contact point between the disk 10 and the spacer 30 is made to generate a bending moment M _{1 ′} that is opposite to the bending moment M ₁ and the protrusion 30 a of the spacer 30 causes the spacer 30 to move. In order to ensure the generation of the bending moment M _{1 ′} , the contact point between the disk 10 and the disk 10 is always located inside the protrusion 21 a and the disk 10 and the disk drive device described with reference to FIG. Also, the bending of the disk 10 can be prevented more reliably.

These disk drive devices have three disks, but a larger number of disks are incorporated,
If some discs are bent over the disc 10 adjacent the hub 21 and the clamp 32, in addition to the spacer 30 adjacent the hub 21 and the disc 10, this spacer is followed by the spacer. By providing a disk drive that also has protrusions on some of the spacers, it is possible to prevent these disks from bending. For example, in FIG.
7 discs are disc 11 and disc 1
2), spacers are placed between each disc, a total of 10 discs are installed, and if the 5th disc from disc 11 is bent, the hub flange 29, a protrusion 21a is provided on the surface of the disk 29 facing the disk 10
In the same manner as the spacer 30, the protrusion 30a is provided on the surface from which the disc 10 is peeled, and is located inside the protrusion 30a of the hub 21 from the spacer 30 to the fourth spacer adjacent to the fifth disc. To provide a protrusion on the surface of each spacer facing the disk 10 and to form a flat on the other area of this surface and on the opposite surface so that each spacer contacts the disk concerned only by the projection. To let With this configuration, the clamp 32
Is attached to the rotor hub 26, and the pressing force from the hub 21 is applied to the contact point between the disk 10 and the spacer 30 to bend the disk 10 so as to project toward the hub flange 29 or the bracket 22. When M ₁ occurs, the protrusion 21 a on the hub flange 29 causes the point of action of the pressure applied from the hub 21 to be outside the contact point between the disk 10 and the spacer 30, and the bending moment M ₁ and the opposite bending In addition to generating the moment M _{1 ′} , the protrusion 30 a of the spacer 30 and the protrusion on the fourth spacer counted from the spacer 30 determine the contact point between the spacer and the disc associated with each spacer as the protrusion 21 a of the hub and the disc 10. It is always located inward of that of and to ensure the occurrence of bending moment M _{1 '} , You can prevent bending of the disc.

FIG. 5 shows still another configuration of the disk drive device of the magnetic disk storage device. This disk drive device is configured similarly to the disk drive device described with reference to FIG. 2, except that the hub 21 does not have a protrusion and only the spacer 31 is provided with a protrusion so that the disk 12 is bent. To prevent it.

The hub 21 is constructed in the same manner as the hub of the spindle motor in FIG. 2, but the flange 29 is formed flat without any protrusion on the surface from which the disk 10 is peeled. The spacer 31 adjacent to the disk 12 is
A protrusion 31a is provided on the surface from which the disc 12 is peeled off, and other regions on this surface and the entire region of the opposite surface are formed flat, and the disc 12 is contacted only by the protrusion 31a. The protrusion 31 a is located inside the protrusion of the clamp 32 that comes into contact with the disc 12, and is disposed on the surface of the spacer 31 facing the disc 12.

In such a disk drive device, the clamp 32 is mounted on the rotor hub 26, the hub 21 is opened by the pressing force from the clamp 32, and the pressing force from the hub 21 acts on the contact point between the clamp 32 and the disk 12. Then
A bending moment M ₂ is generated with the contact point between the disk 12 and the spacer 31 as a fulcrum, and the disk 12 is clamped 3
2, when the protrusion 31a on the spacer 31 positions the contact point between the clamp 32 and the disk 12 to the outside of the contact point between the spacer 31 and the disk 12, The bending moment M _{2 ′} opposite to the bending moment M ₂ is generated, so that the bending of the disk 12 is prevented.

Also in this disc drive, a larger number of discs are incorporated, and the disc 12 and the hub 2 are incorporated.
In case of bending of several discs facing 1 the protrusions on the spacers 32 adjacent to the clamp 32 and the disc 12 as well as some spacers following this spacer towards the hub 21. By using the disk drive device having the above, it is possible to prevent the bending of these disks. For example, in FIG. 5, seven discs are placed between discs 12 and 11, spacers are placed between each disc, for a total of ten discs incorporated, counting from disc 12, for example. When the discs up to the fifth are curved, a protrusion 31a is provided on the surface of the spacer 31 where the disc 12 is peeled off, and the spacer 31 is counted up to the fourth spacer adjacent to the fifth disc. Protrusions similar to the spacers 31 are provided on the stripped surface of each of the spacers 10 and the other areas of these surfaces and the entire area of the opposite surface are made flat so that each spacer is related only by the protrusions. To contact. By such a configuration, the hub 32 is mounted on the rotor clamp 26, joined by pressure from the clamp 32, the bending moment M ₂ to try to Niwan song to protrude toward the disk 12 to the clamp 32
Is generated, the protrusion 31a on the spacer 31 causes the point of action of the pressing force from the clamp 32 to be inside the contact point between the disk 12 and the spacer 31, and the bending moment M ₂ opposite to the bending moment M _{2 In addition} to generating _{2 '} , the protrusions on each of the spacers up to the fourth spacer 31 counts the contact point between each spacer and the disc associated with these spacers inside the clamp 32 and the disc 12. Since the bending moment M _{2 ′} is surely generated by arranging at the position, it is possible to prevent the bending of the disc up to the fifth position.

FIG. 6 shows still another configuration of the disk drive device of the magnetic disk storage device. This disk drive device is configured similarly to the disk drive device described with reference to FIG. 2, except that not only the hub 21 but also the spacer 31 is provided with a protrusion 31a, so that the disk
Also, the bending of the disk 12 can be prevented.

The hub 21 is provided with a protrusion 21a on the surface of the flange 29 where the disc 10 is peeled off, and the other region on this surface is formed flat so that the protrusion 21a alone contacts the disc 10. . Further, the spacer 31 is provided with a protrusion 31a on the surface from which the disc 12 is peeled off, and the other region on this surface and the entire region on the opposite surface are formed flat so that the protrusion 31a alone makes contact with the disc 10. ing. Of these protrusions, the protrusion 2 on the hub
1 a is located outside the contact point between the hub flange 29 and the disk 12 that occurs when the clamp 32 is mounted, and is located on the surface of the hub flange 29, and the protrusion 31 a is the clamp 32.
Are located inside the contact points between the clamp 32 and the disk 12 that occur when the disk is mounted, and are respectively arranged on the surface of the spacer 31 from which the disk 12 is peeled.

In this disk drive device, the clamp 32 is mounted on the rotor hub 26 and the pressing force from the hub 21 contacts the disk 10 and the spacer 30, as in the disk drive device described with reference to FIG. Join the dots,
The disk 10 is attached to the hub flange 29 or the bracket 2.
When a bending moment M ₁ that tends to bend toward 2 is generated, the protrusion 21a on the flange 29 causes the point of action of the pressing force from the hub 21 to be the contact point between the disk 10 and the spacer 30. by outside the generates a moment M ₁ and the opposite bending moment M _{1 'bent,} to maintain the disc 10 in the flat. At the same time, the protrusion 31a on the spacer 31 positions the contact point between the clamp 32 and the disk 12 outside the contact point between the disk 12 and the spacer 31, and the point of action of the pressing force from the hub 21 between the disk 12 and the clamp 32. of by inward from the contact point, to generate a bending bending moment M ₂ of the direction opposite to the moment M _{2 ',} to maintain the disc 12 in the flat. Then, since the disc 10 and the disc 12 become flat, the bending of the intermediate disc 11 is also prevented.

FIG. 7 shows still another configuration of the disk drive device of the magnetic disk storage device. This disk drive device is configured similarly to the disk drive device described with reference to FIG. 6, except that not only the hub 21 and the clamp 32 but also the spacer 30 facing the hub 21 is provided with the protrusion 30a. , So that the bending of the disks 10 to 12 can be prevented more completely.

The hub 21 is provided with a protrusion 21a on the surface of the flange 29 where the disc 10 is peeled off, and the other region on this surface is formed flat so that the protrusion 21a alone contacts the disc 10. . The spacer 30 is provided with a protrusion 30a on the surface from which the disc 10 is peeled off, and is formed flat on the other region of this surface and the entire region on the opposite surface so that the protrusion 21a alone contacts the disc 10. Has been forced to. The spacer 31 is provided with a protrusion 31a on the surface from which the disc 12 is peeled, the other region on this surface and the entire region on the opposite surface are formed flat, and is made to contact the disc 10 only by the protrusion 31a. . Of these protrusions, protrusion 2
1a is a disc 1 which is produced when the clamp 32 is mounted
0 is located outside the contact point between the clamp 30 and the surface of the hub flange 29, the protrusion 30a is inside the protrusion 21a on the hub 21, and the protrusion 31a is the clamp 32 generated when the clamp 32 is mounted. They are arranged inside the contact points with the disk 12, respectively.

The hub 21 and the spacer 30 as described above,
In the disk drive device having 31, the clamp 32 is attached to the rotor hub 26 and the pressing force from the hub 21 is applied to the contact point between the disk 10 and the spacer 30, as in the disk drive device described with reference to FIG. , Disk 10
The bending moment M to bend the hub flange 29 or the bracket 22 so as to project.
_{When 1} occurs, the protrusion 21a on the flange 29 causes the point of action of the pressing force from the hub 21 to be outside the contact point between the disk 10 and the spacer 30, and the bending moment M
₁ and with generating a bending moment M _{1 'opposite,} always is located inside than the projecting 21a and the disc 10 the point of contact with the protrusion 30a is the spacer 30 and the disk 10 in the spacer 30, the bending moment M
The occurrence of _{1 'by} ensured, to maintain the disc 10 in the flat. At the same time, the protrusion 31a of the spacer 31 positions the contact point between the clamp 32 and the disk 12 to the outside of the contact point between the disk 12 and the spacer 31, and the action point of the pressing force from the hub 21 becomes the disk 12 and the clamp 32. Bending moment M ₂
Bending moment M _{2 ′} opposite to that can be generated to more reliably prevent the bending of all the disks 10 to 12. Therefore, even when the disks are made thinner, the number of disks is increased, and the hub 21 is made lighter,
You can prevent the bending of all discs.

In these disk drive devices, the disks 10 to 12 are kept flat as described above,
Even if the head and slider have the same gap at any position on each disk and the flying height of the head or slider is reduced, the read voltage of each head is the same.
By increasing the recording density, it is possible to obtain a compact magnetic disk storage device having a large storage capacity.

Even if the disk drive device is composed of only one disk, it is possible to prevent the disk from bending by providing the hub with a protrusion. This disk drive will be described with reference to FIG. 2. Only the disk 10, a hub 21 located on one side of the disk 10 and having a surface in contact with the disk 10, and the disk 10 are crimped onto the surface of the hub 21. In addition to the clamp 32, the hub 21 has a projection 21a on the surface of the disk 10.
At this time, the clamp 32 is mounted, the hub 21 is opened by the pressing force of the clamp 32, and the contact point between the hub 21 and the disc 10 is located inside the contact point between the disc 10 and the clamp 32. When the bending moment M ₂ generated by using the contact point with the fulcrum as the fulcrum tries to bend the disk 10 so as to project toward the hub 32, the projection 21 a on the hub 21 contacts the disk 10 and the clamp 32. The bending moment M _{2 ′} of the opposite peeling is set to the outside of the point so that the disc 10
Occurs with the contact point between the clamp and the clamp 32 as a fulcrum,
The bending of the disk 10 is prevented.

[0050]

As described above, the disk-type storage medium driving device of the present invention can eliminate the curvature of the disk, and even if it exists, it can be made extremely small. When applied to a disk storage device, the distance between the head and the disk can be narrowed to increase the recording density, and the size and size of the storage can be reduced. This can be achieved without the use of ones whose accuracy varies significantly, so that one can reliably obtain a stable performance.

[Brief description of drawings]

FIG. 1 is a diagram for explaining an internal structure of a head disk assembly of a magnetic disk storage device in which a drive device for a disk storage medium of the present invention is incorporated.

FIG. 2 is a cross-sectional view showing an embodiment of a disk-type storage medium drive device of the present invention.

FIG. 3 is a cross-sectional view showing another embodiment of the disk-type storage medium drive device of the present invention.

FIG. 4 is a cross-sectional view showing still another embodiment of the drive device for the disk-shaped storage medium of the present invention.

FIG. 5 is a sectional view showing still another embodiment of the drive device for the disk-shaped storage medium of the present invention.

FIG. 6 is a cross-sectional view showing still another embodiment of the drive device for the disk-shaped storage medium of the present invention.

FIG. 7 is a cross-sectional view showing still another embodiment of the drive device for the disk-shaped storage medium of the present invention.

FIG. 8 is a cross-sectional view of a conventional disk-type storage medium driving device.

FIG. 9 is a diagram for explaining a deformed state in a conventional disk-type storage medium drive device.

FIG. 10 is a diagram showing the relationship between the curvature of the disk and the flying height of the head in the magnetic disk storage device.

[Explanation of symbols]

 10-12 ... Disk type storage medium 21 ... Hub 30, 31 ... Spacer 32 ... Clamp 21a, 30a, 31a ... Projection

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Kenjiro Kai Kai 2880, Kokufu, Odawara, Kanagawa Stock Company Hitachi Storage Systems Division (72) Koichi Ono 2880, Kozu, Odawara, Kanagawa Hitachi Storage Co., Ltd. System Division

Claims (9)

[Claims] 1. A plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a laminate composed of the disk-shaped storage media and the spacers are fitted,
A drive for a disk storage medium comprising a hub having a surface for contacting the disk storage medium located on one side of the inlaid stack and a clamp for crimping the stack to said surface of the hub, the hub comprising: A contact point formed between the disk-shaped storage medium adjacent to the hub and a spacer adjacent to the disk-shaped storage medium located on the surface and attached with a clamp, and a protrusion disposed outside the contact surface. A drive device for a disk-shaped storage medium, characterized in that 2. A plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a laminate comprising the disk-shaped storage media and the spacers are fitted,
In a drive for a disk-shaped storage medium comprising a hub having a surface for contacting the disk-shaped storage medium located on one side of the fitted stack and a clamp for crimping the stack to said surface of the hub, A contact point in which a spacer adjacent to an adjacent disk storage medium is located on the surface facing the disk storage medium adjacent to the hub and is formed between the hub and the disk storage medium adjacent thereto by mounting a clamp. Alternatively, the drive device for the disk-shaped storage medium is characterized in that the drive device is provided with a protrusion arranged inside the contact surface. 3. A plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a stack of the disk-shaped storage media and the spacers are fitted,
A drive for a disk storage medium comprising a hub having a surface for contacting the disk storage medium located on one side of the inlaid stack and a clamp for crimping the stack to said surface of the hub, the hub comprising: A contact point formed between the disk-shaped storage medium adjacent to the hub and a spacer adjacent to the disk-shaped storage medium located on the surface and attached with a clamp, and a protrusion disposed outside the contact surface. And a spacer adjacent to the disk-shaped storage medium adjacent to the hub is located on the peeled surface of the disk-shaped storage medium adjacent to the hub and by mounting a clamp, the hub and the disk-shaped storage medium adjacent thereto are A disk-shaped storage medium, characterized in that it is provided with protrusions arranged inside contact points or contact surfaces formed between them. Of the drive unit. 4. A plurality of disc-shaped storage media, spacers arranged between the disc-shaped storage media, and a stack of the disc-shaped storage media and the spacers are fitted,
A drive for a disk storage medium comprising a hub having a surface for contacting the disk storage medium located on one side of the inlaid stack and a clamp for crimping the stack to said surface of the hub, the hub comprising: A contact point formed between the disk-shaped storage medium adjacent to the hub and a spacer adjacent to the disk-shaped storage medium located on the surface and attached with a clamp, and a protrusion disposed outside the contact surface. In addition, a plurality of spacers, which are arranged in order from the spacer adjacent to the hub, are provided with a protrusion arranged inside the protrusion of the hub on the surface of the disk-shaped storage medium adjacent to the hub. A drive device for a characteristic disk-shaped storage medium. 5. A plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a laminate comprising the disk-shaped storage media and the spacers are fitted,
In a drive for a disk-shaped storage medium, comprising: a hub having a surface for contacting the disk-shaped storage medium located on one side of the fitted stack; and a clamp for pressing the stack onto the surface of the hub. A contact point in which a spacer adjacent to an adjacent disk-shaped storage medium is located on the peeled surface of the disk-shaped storage medium adjacent to the clamp and is formed between the clamp and the disk-shaped storage medium adjacent to the clamp by mounting the clamp. Alternatively, the drive device for the disk-shaped storage medium is characterized in that the drive device is provided with a protrusion arranged inside the contact surface. 6. A plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a stack of the disk-shaped storage media and the spacers are fitted,
In a drive for a disk-shaped storage medium, comprising: a hub having a surface for contacting the disk-shaped storage medium located on one side of the fitted stack; and a clamp for pressing the stack onto the surface of the hub. A plurality of spacers, arranged in sequence from the clamp to the hub, first with spacers adjacent to adjacent disks, are located on the exposed surface of the disk-shaped storage medium adjacent to the clamps and are adjacent to the clamps by attachment of the clamps. Drive device for a disk-shaped storage medium, comprising a contact point formed between the contact point and a contact surface or a protrusion disposed inside the contact surface. 7. A plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a stack of the disk-shaped storage media and the spacers are fitted,
A drive for a disk storage medium comprising a hub having a surface for contacting the disk storage medium located on one side of the inlaid stack and a clamp for crimping the stack to said surface of the hub, the hub comprising: A contact point formed between the disk-shaped storage medium adjacent to the hub and a spacer adjacent to the disk-shaped storage medium located on the surface and attached with a clamp, and a protrusion disposed outside the contact surface. And the spacer adjacent to the disc-shaped storage medium adjacent to the clamp is located on the peeled surface of the disc-shaped storage medium adjacent to the hub and by mounting the clamp between the clamp and the disc-shaped storage medium adjacent to the clamp. A disc characterized in that it is provided with protrusions arranged inside the contact points or contact surfaces formed between them. Drive of click-type storage medium. 8. A plurality of disk-shaped storage media, spacers arranged between the disk-shaped storage media, and a stack of the disk-shaped storage media and the spacers are fitted,
A drive for a disk storage medium comprising a hub having a surface for contacting the disk storage medium located on one side of the inlaid stack and a clamp for crimping the stack to said surface of the hub, the hub comprising: A contact point formed between the disk-shaped storage medium adjacent to the hub and a spacer adjacent to the disk-shaped storage medium located on the surface and attached with a clamp, and a protrusion disposed outside the contact surface. And a spacer adjacent to the disk-shaped storage medium adjacent to the hub is formed on the surface of the disk-shaped storage medium adjacent to the hub facing the disk-shaped surface and is formed between the hub and the disk-shaped storage medium adjacent thereto by mounting a clamp. Disk-shaped storage medium having a protrusion located inside the contact point or contact surface and adjacent to the clamp Adjacent spacers are located on the peeled surface of the disk-shaped storage medium adjacent to the hub and inside the contact point or contact surface formed between the clamp and the disk-shaped storage medium adjacent to the clamp by mounting the clamp. A drive device for a disk-shaped storage medium, characterized in that it comprises a protrusion arranged. 9. A disk storage medium, a hub having a surface for contacting the disk storage medium located on one side of the fitted disk storage medium, and a disk storage medium crimped to the surface of the hub. A drive for a disk-shaped storage medium including a clamp, the hub being located on the surface facing the disk-shaped storage medium and the contact point or the point formed between the clamp and the disk-shaped storage medium by mounting the clamp. A disk drive device comprising a protrusion arranged outside the contact surface.